CN219369728U

CN219369728U - Water ecology detection device

Info

Publication number: CN219369728U
Application number: CN202320186174.6U
Authority: CN
Inventors: 沈飞; 邓细钢; 刘志东
Original assignee: Wuhan Huayi Zhongtong Technology Co ltd
Current assignee: Wuhan Huayi Zhongtong Technology Co ltd
Priority date: 2023-02-02
Filing date: 2023-02-02
Publication date: 2023-07-18
Anticipated expiration: 2033-02-02

Abstract

The utility model discloses a water ecology detection device, which belongs to the technical field of environment detection and comprises: the device comprises a mounting box, a sample storage frame, a flow guide piece, a rotary driving piece and a lifting driving piece, wherein a floating ball is arranged on the periphery of the mounting box; the sample storage frame is arranged below the mounting box, a sample injection cavity for entering a water sample is formed in the center of the inside of the sample storage frame, and a plurality of sample storage cavities are formed on the periphery of the sample injection cavity around the inner outer side of the sample storage frame; the flow guiding piece comprises a flow guiding frame, the flow guiding frame is arranged between the sample injection cavity and the sample storage cavity to separate the sample injection cavity and the sample storage cavity, and one side of the flow guiding frame is provided with a flow guiding hole; the driving end of the rotary driving piece is connected with the flow guiding frame; the lifting driving piece is arranged in the mounting box, and the driving end of the lifting driving piece is connected with the sample storage frame; the device can realize water quality detection of different water layers, can also continuously store water samples of different water layers, and is convenient for further analysis and detection of the water samples.

Description

Water ecology detection device

Technical Field

The utility model relates to the technical field of environment detection, in particular to a water ecology detection device.

Background

Water is an indispensable resource for our survival, and with the gradual increase of industrial level, the discharge of industrial sewage is accompanied by extensive pollution of water, which causes serious water pollution. In order to protect and improve the environmental water body and reduce the pollution hazard and the loss caused by the pollution hazard to the greatest extent, the technological means are adopted to strengthen the acquisition and the comprehensive analysis of the environmental water body information besides increasing the treatment strength of pollution sources.

The utility model discloses a CN217717709U provides a river course water ecological environment monitoring device, and it includes support column and capstan winch, and the support column passes through the base to be fixed by the river course, and the capstan winch work is paid out, and the capstan winch unwrapping wire places the water quality monitor into the aquatic of river course, can carry out water quality monitoring to the river course through the water quality monitor; but the device can't draw the water sample that detects, and current device still can set up sampling device at detection device side and take a sample, but when taking a sample to different water levels, need sampling device back and forth movement between each water level and storage sample box, waste time and energy.

Disclosure of Invention

The utility model aims to overcome the technical defects, and provides a water ecology detection device which solves the technical problems in the prior art.

In order to achieve the above technical purpose, the technical solution of the present utility model provides an apparatus for detecting water ecology, comprising:

the installation box is provided with a floating ball at the periphery;

the sample storage frame is arranged below the mounting box, a sample injection cavity for entering a water sample is formed in the center of the inside of the sample storage frame, a plurality of sample storage cavities are formed on the outer side of the inside of the sample storage frame around the periphery of the sample injection cavity, each sample storage cavity is communicated with the sample injection cavity through a sample injection groove, and a detection head for detecting water quality is arranged in each sample injection cavity;

the flow guiding piece comprises a flow guiding frame, the flow guiding frame is arranged between the sample injection cavity and the sample storage cavity to separate the sample injection cavity and the sample storage cavity, and one side of the flow guiding frame is provided with a flow guiding hole;

the driving end of the rotary driving piece is connected with the flow guiding frame and is used for driving the flow guiding frame to intermittently rotate so that the flow guiding holes sequentially correspond to the plurality of sample injection grooves;

the lifting driving piece is arranged on the mounting box, and the driving end of the lifting driving piece is connected with the sample storage frame and used for driving the sample storage frame to move relative to the mounting box so as to be placed on water layers with different depths.

In some embodiments, the sample storage frame comprises an outer frame, an inner frame and a top plate, wherein the inner frame is arranged in the outer frame and is connected with the outer frame in a coaxial way, the top plate is covered on the outer frame, a plurality of partition plates are uniformly arranged between the inner frame and the outer frame around the inner frame, and the sample introduction grooves are respectively correspondingly arranged on the inner frame.

In some embodiments, a bottom plate is disposed on one side of the outer frame and the inner frame away from the top plate, and through holes are disposed at positions of the top plate and the bottom plate corresponding to the inner frame.

In some embodiments, an annular protrusion is formed on the outer side of the top plate in a direction close to the outer frame, an annular groove in butt fit with the annular protrusion is formed on the outer side of the outer frame, and a waterproof frame is arranged between the annular groove and the annular protrusion.

In some embodiments, the flow guiding member further comprises a connecting plate connected with the flow guiding frame, the connecting plate is rotatably connected with the bottom plate, and one end of the through hole on the bottom plate penetrates through the bottom plate and is communicated with the inside of the inner frame.

In some embodiments, a circular groove is formed in one side of the connecting plate, and an inner gear is arranged on the inner wall of the circular groove.

In some embodiments, the rotary driving member includes a first motor, a turntable and teeth, the turntable is rotationally disposed in the circular groove, the teeth are disposed on one side of the turntable and engaged with the internal gear, and a driving shaft of the first motor is connected to the turntable to drive the turntable to rotate so that the teeth intermittently stir the internal gear to rotate by a set angle.

In some embodiments, the lifting drive member comprises a second motor, a threaded rod and a sleeve, the threaded rod is rotatably arranged in the mounting box, the sleeve is in threaded connection with the threaded rod, one end of the sleeve is connected with the sample storage frame, and a driving shaft of the second motor is connected with the threaded rod.

In some embodiments, the side of the threaded rod is provided with a loop bar arranged in parallel with the threaded rod, the loop bar is arranged in the mounting box, one end of the loop bar is connected with a sliding rod in a sliding manner, and one end of the sliding rod is connected with the sample storage frame.

In some embodiments, a top floating plate is provided above the mounting box, and an annular floating plate is provided on the perimeter side of the mounting box.

Compared with the prior art, the utility model has the beneficial effects that: through the sample storage frame and the rotary driving piece, the rotary driving piece can drive the sample storage frame to enter into water layers with different depths, and the detection head can be used for detecting the water quality at the corresponding position, so that the water quality detection of different water layers can be realized;

through water conservancy diversion spare and the rotary drive spare that set up, when the water layer of different degree of depth is arranged in to the sample storage frame, utilize rotary drive spare can drive the water conservancy diversion hole in proper order with a plurality of sampling slot correspond, make hydroenergy enter into corresponding sample storage intracavity, can preserve the water sample of different water layers in succession to follow-up carry out further analysis detection to the water sample again.

Drawings

FIG. 1 is a front view of an embodiment of a water ecology detection device according to the present utility model;

FIG. 2 is a perspective view of the storage frame of the water detection device of FIG. 1;

FIG. 3 is a front cross-sectional view of the water quality detection device of FIG. 1 in a storage frame installation;

FIG. 4 is a partial perspective view of a sample storage frame of the water detection device of FIG. 1;

FIG. 5 is a bottom view of the connection plate of the water detection device of FIG. 1;

fig. 6 is an enlarged view at a in fig. 3.

In the figure: 1. a mounting box; 11. a floating ball; 12. a top floating plate; 13. an annular floating plate;

2. a sample storage frame; 21. a sample introduction cavity; 22. a sample storage cavity; 23. a sample introduction groove; 24. a detection head; 25. an outer frame; 26. an inner frame; 27. a top plate; 28. a partition plate; 29. a bottom plate; 210. a through hole; 211. an annular protrusion; 212. an annular groove; 213. a waterproof frame;

3. a flow guide; 31. a flow guiding frame; 32. a deflector aperture; 33. a connecting plate; 34. a circular groove; 35. an internal gear;

4. a rotary driving member; 41. a first motor; 42. a turntable; 43. teeth;

5. a lifting driving member; 51. a second motor; 52. a threaded rod; 53. a sleeve;

6. a loop bar; 7. and a slide bar.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

As shown in fig. 1 and 2, the present utility model provides an apparatus for detecting water ecology, comprising: mounting box 1, sample storage frame 2, water conservancy diversion piece 3, rotation driving piece 4 and lift driving piece 5.

A floating ball 11 is arranged on the periphery of the mounting box 1.

The sample storage frame 2 is arranged below the mounting box 1, a sample injection cavity 21 for entering a water sample is formed in the center of the inside of the sample storage frame 2, a plurality of sample storage cavities 22 are formed on the outer side of the inside of the sample storage frame 2 around the periphery of the sample injection cavity 21, the sample storage cavities 22 are communicated with the sample injection cavity 21 through sample injection grooves 23, and a detection head 24 for detecting water quality is arranged in the sample injection cavity 21.

The flow guiding member 3 comprises a flow guiding frame 31, the flow guiding frame 31 is arranged between the sample injection cavity 21 and the sample storage cavity 22 to separate the sample injection cavity 21 and the sample storage cavity 22, and one side of the flow guiding frame 31 is provided with a flow guiding hole 32.

The driving end of the rotary driving piece 4 is connected with the diversion frame 31 and is used for driving the diversion frame 31 to intermittently rotate so that the diversion holes 32 sequentially correspond to the plurality of sample injection grooves 23.

The lifting driving piece 5 is arranged on the mounting box 1, and the driving end of the lifting driving piece 5 is connected with the sample storage frame 2 and is used for driving the sample storage frame 2 to move relative to the mounting box 1 so as to be placed in water layers with different depths.

In this device, set up floater 11 in the week side of mounting box 1, make mounting box 1 float on the surface of water in the during operation, be equipped with sample introduction cavity 21 and sample storage cavity 22 respectively in sample storage frame 2, utilize lift driver 5 can drive sample storage frame 2 and enter into the water layer of different degree of depth, make water enter into sample introduction cavity 21, utilize detection head 24 to detect water quality, can realize the quality of water detection to different water layers, and, sample introduction cavity 21 and sample storage cavity 22 can be separated in the setting of guide frame 31, play the effect of shutoff part sample introduction groove 23, utilize rotary driver 4 can drive the water conservancy diversion hole 32 of guide frame 31 to correspond with a plurality of sample introduction groove 23 in proper order, make sample introduction cavity 21 can communicate with one of them sample storage cavity 22 in proper order, when entering into next water level, rotary driver 4 drives guide frame 31 and rotates and makes water conservancy diversion hole 32 and another sample introduction groove 23 correspond, the water just can flow to sample storage cavity 22 through sample introduction cavity 21 and store, the in-storing frame 2 position's in-process, utilize a plurality of sample storage cavity 22 to deposit different water layers respectively.

As shown in fig. 1, in some embodiments, the lifting driving member 5 includes a second motor 51, a threaded rod 52 and a sleeve 53, the threaded rod 52 is rotationally disposed in the mounting box 1, the sleeve 53 is in threaded connection with the threaded rod 52, one end of the sleeve 53 is connected with the sample storage frame 2, a driving shaft of the second motor 51 is connected with the threaded rod 52, a sleeve rod 6 arranged in parallel with the threaded rod 52 is disposed on a side of the threaded rod 52, the sleeve rod 6 is fixedly disposed in the mounting box 1, one end of the sleeve rod 6 is slidably connected with the slide rod 7, one end of the slide rod 7 is connected with the sample storage frame 2, the second motor 51 can drive the threaded rod 52 to rotate, the sleeve 53 is slidably connected with the mounting box 1 through limiting of the sleeve rod 6 and the slide rod 7, and when the threaded rod 52 rotates, the sleeve 53 can be driven to move upwards or downwards so as to drive the sample storage cavity 22 to translate upwards or downwards, so that the device can detect and collect water of different water layers, and simultaneously, bottom ends of the two slide rods 7 are fixedly connected with two sides of the top plate 27 respectively.

In order to improve the levitation stability of the mounting box 1, as shown in fig. 1, in some embodiments, a top floating plate 12 is provided above the mounting box 1, and an annular floating plate 13 is provided on the circumferential side of the mounting box 1.

As shown in fig. 2 to 4, in some embodiments, the sample storage frame 2 includes an outer frame 25, an inner frame 26 and a top plate 27, the inner frame 26 is disposed in the inner frame 25 and fixedly connected with the outer frame 25 in a coaxial manner, the top plate 27 is disposed on the outer frame 25, a plurality of partition plates 28 are uniformly disposed between the inner frame 26 and the outer frame 25 around the inner frame 26, sealing plate pads are disposed on tops of the inner frame 26, the outer frame 25 and the partition plates 28 and are closely attached to the top plate 27, a sample introduction cavity 21 is formed in the inner frame 26, a plurality of sample storage cavities 22 are formed between the inner frame 26 and the outer frame 25 by separating the partition plates 28, sample introduction grooves 23 are respectively disposed on the inner frame 26, a bottom plate 29 is disposed on one side of the outer frame 25 and the inner frame 26 away from the top plate 27, through holes 210 are disposed on positions of the top plate 27 and the bottom plate 29 corresponding to the inner frame 26, and in operation, water can enter the inner frame 26 through the through holes 210 on the bottom plate 29 and the top plate 27, and the detection head 24 is mounted on the bottom of the top plate 27 and is disposed in the inner frame 26, so that water samples can be detected, when the water samples are replaced, the water level can be discharged, and the water level detection is achieved.

In some embodiments, as shown in fig. 6, an annular protrusion 211 is formed on the outer side of the top plate 27 in a direction close to the outer frame 25, an annular groove 212 in butt-joint fit with the annular protrusion 211 is formed on the outer side of the outer frame 25, so that the top plate 27 and the outer frame 25 can be detached and fixed by bolts, after the top plate 27 is taken out, water samples in the sample storage frame 2 can be conveniently taken out, a waterproof frame 213 is arranged between the annular groove 212 and the annular protrusion 211, the waterproof frame 213 is made of rubber, and the tightness of the sample storage frame 2 is further improved.

Further, the sample introduction grooves 23 and the guide holes 32 are the same in size, and inner frame 26 wall surfaces with widths larger than the guide holes 32 are reserved between two adjacent sample introduction grooves 23, so that when the water level needs to be replaced, the guide holes 32 can be driven to rotate between the two guide holes 32 by using the rotary driving piece 4, the guide holes 32 correspond to the wall surfaces of the inner frame 26, and accordingly all sample storage cavities 22 can be sealed when the water level is replaced, and inaccurate storage of water samples in the sample storage cavities 22 is avoided.

As shown in fig. 3, in some embodiments, the flow guiding member 3 further includes a connection plate 33 connected to the flow guiding frame 31, where the connection plate 33 is rotatably connected to the bottom plate 29, and one end of the through hole 210 on the bottom plate 29 penetrates through the bottom plate 29 to communicate with the interior of the inner frame 26.

As shown in fig. 5, in some embodiments, a circular groove 34 is formed on one side of the connecting plate 33, an inner gear 35 is disposed on an inner wall of the circular groove 34, the rotary driving member 4 includes a first motor 41, a turntable 42 and teeth 43, the turntable 42 is rotatably disposed on the circular groove 34 and rotatably connected to the connecting plate 33, the teeth 43 are disposed on one side of the turntable 42 and are engaged with the inner gear 35, the first motor 41 is mounted on the bottom plate 29 and has a driving shaft connected to the turntable 42, the driving shaft can drive the turntable 42 to rotate so that the teeth 43 intermittently stir the inner gear 35 by a set angle, when the diversion hole 32 corresponds to the sample introduction groove 23, the driving shaft of the first motor 41 rotates one circle to drive the diversion hole 32 of the diversion frame 31 to rotate between the two diversion holes 32, and at this time corresponds to the inner wall of the inner frame 26, so that a plurality of sample storage cavities 22 can be sealed, so that when the sample storage frame 2 is placed in the sampling position, after the turntable 42 is driven by the first motor 41 to rotate one circle, the diversion hole 32 can be driven to correspond to the next sample storage cavity 22, so that the water samples can be stored.

Working principle: when the device is used, the device is placed on the water surface, the second motor 51 is used for driving the threaded rod 52 to rotate, so that the sleeve 53 drives the sample storage frame 2 to move downwards to a set position, water enters the inner frame 26 through the through hole 210, water quality is detected through the detection head 24, at the moment, the first motor 41 is driven to drive the rotary table 42 to rotate for one circle, the teeth 43 drive the connecting plate 33 and the guide frame 31 to rotate for a set angle, the guide hole 32 corresponds to the sample introduction groove 23, at the moment, a water sample can enter the sample storage cavity 22 through the sample introduction groove 23 for storage, when the water sample moves to the next water level, the rotary driving piece 4 is used for driving the guide hole 32 to rotate to correspond to the wall surface of the inner frame 26 again, each sample storage cavity 22 is sealed, then the lifting driving piece 5 is used for driving the sample storage frame 2 to replace, and after the replacement, the rotary driving piece 4 is used for sequentially driving the guide hole 32 to correspond to the downwards moving sample introduction groove 23 for sampling.

According to the utility model, through the sample storage frame 2 and the rotary driving piece 4, the rotary driving piece 4 can drive the sample storage frame 2 to enter water layers with different depths, and the detection head 24 can be used for detecting water quality at corresponding positions, so that water quality detection of different water layers can be realized;

according to the utility model, through the arranged diversion piece 3 and the rotary driving piece 4, when the sample storage frame 2 is placed in water layers with different depths, the rotary driving piece 4 can be utilized to drive the diversion holes 32 to sequentially correspond to the plurality of sample introduction grooves 23, so that water can enter the corresponding sample storage cavities 22, water samples of different water layers can be continuously stored, and further analysis and detection can be conveniently carried out on the water samples.

The above-described embodiments of the present utility model do not limit the scope of the present utility model. Any other corresponding changes and modifications made in accordance with the technical idea of the present utility model shall be included in the scope of the claims of the present utility model.

Claims

1. A water ecology detection device, comprising:

the installation box is provided with a floating ball at the periphery;

the sample storage frame is arranged below the mounting box, a sample injection cavity for entering a water sample is formed in the center of the inside of the sample storage frame, a plurality of sample storage cavities are formed on the outer side of the inside of the sample storage frame around the periphery of the sample injection cavity, the sample storage cavities are communicated with the sample injection cavity through sample injection grooves, and a detection head for detecting water quality is arranged in the sample injection cavity;

the flow guide piece comprises a flow guide frame, the flow guide frame is arranged between the sample injection cavity and the sample storage cavity and used for separating the sample injection cavity and the sample storage cavity, and one side of the flow guide frame is provided with a flow guide hole;

2. The water ecology detection device of claim 1, wherein the sample storage frame comprises an outer frame, an inner frame and a top plate, the inner frame is arranged in the outer frame and is connected with the outer frame in a coaxial way, the top plate is covered on the outer frame, a plurality of partition plates are uniformly arranged between the inner frame and the outer frame around the inner frame, and the sample introduction grooves are respectively correspondingly arranged in the inner frame.

3. The water ecology detection device of claim 2, wherein a bottom plate is arranged on one side of the outer frame and the inner frame away from the top plate, and through holes are formed in the positions of the top plate and the bottom plate corresponding to the inner frame.

4. The water ecology detection device of claim 2 wherein an annular protrusion is formed on the outer side of the top plate in a direction approaching the outer frame, an annular groove in butt joint with the annular protrusion is formed on the outer side of the outer frame, and a waterproof frame is arranged between the annular groove and the annular protrusion.

5. A water ecology detection device according to claim 3 wherein the deflector further comprises a connection plate connected to the deflector frame, the connection plate being rotatably connected to the base plate, one end of the through hole in the base plate being in communication with the interior of the inner frame through the base plate.

6. The water ecology detection device of claim 5 wherein a circular groove is formed in one side of the connection plate, and an internal gear is arranged on the inner wall of the circular groove.

7. The water ecology detection device of claim 6 wherein the rotary driving member comprises a first motor, a rotary table and teeth, the rotary table is rotatably arranged in the circular groove, the teeth are arranged on one side of the rotary table and are meshed with the internal gear, and a driving shaft of the first motor is connected with the rotary table and is used for driving the rotary table to rotate so that the teeth intermittently stir the internal gear to rotate by a set angle.

8. The water ecology detection device of claim 1 wherein the lifting drive comprises a second motor, a threaded rod and a sleeve, the threaded rod is rotatably disposed in the mounting box, the sleeve is in threaded connection with the threaded rod, one end of the sleeve is connected with the sample storage frame, and a drive shaft of the second motor is connected with the threaded rod.

9. The water ecology detection device of claim 8 wherein a loop bar is arranged on the side of the threaded rod and is arranged in parallel with the threaded rod, the loop bar is arranged in the mounting box, one end of the loop bar is connected with a sliding bar in a sliding manner, and one end of the sliding bar is connected with the sample storage frame.

10. The water ecology detection device of claim 1 wherein a top floating plate is provided above the mounting box and an annular floating plate is provided on the perimeter of the mounting box.